In this thesis, different methods of fabricating nanostructures on the surface of single crystal silicon for antireflection were investigated and the influences of these nanostructures on the conversion efficiency of the solar cell were studied. Three methods were used to make nanostructures. The first method was wet etching method which has been wildly used in the solar cell industry. KOH solution was used to wet etch Si surface and many small pyramidal structures were formed after the wet etching. The second method was using reactive ion etching with Ag nanoclusters as etch mask. In this method, a thin Ag film was deposited on the silicon surface first, then the sample was thermally annealed to let Ag film dewet into Ag clusters and serves us etch mask. After reactive ion etching, Si-nanopillars were formed on the Si surface. The third method was using the electron cyclotron resonance (ECR) to make the nanotips structure. The SiC clusters which were formed on the Si substrate in the beginning of ECR process could be used for etch-mask. After the unmasked region is etched by Ar and H2, Si-nanotips were formed on the surface. Fourier transform spectrometer was used to measure the reflection of the surface with nanostructures in the VIS and NIR regions. The samples with nanopillar and nanotip structures were both found to have lower reflection in these spectral regions than the sample made by using wet etching. Solar cells were then made by using thermal diffusion of n-type dopants into the samples, and we found that the solar cells with the nanopillar structures had the best conversion efficiency. The efficiency is enhanced by 82% over the solar cell made with conventional method. On the other hand, although the sample with nanotip structure has excellent antireflection property, after making into solar cell it has very poor efficiency. This is because the nanotip structures were destroyed in the high temperature process in making the solar cell.